Kevin M. Okleberry

Inhibition of Friend Murine Leukemia virus activity by guanosine/thymidine oligonucleotides

Oligonucleotides consisting of only deoxyguanosine and deoxythymidine were stable in culture and were able to significantly inhibit Friend Murine Leukemia Virus (FMLV) production in acute cell culture assay systems. The oligonucleotides did not share homology with, or possess any complementary (antisense) sequence motifs to the FMLV genome. The guanosine/thymidine-containing oligonucleotides (GTOs) which demonstrated anti-FMLV activity in acute infection assays were synthesized with natural phosphodiester (PD) linkages (backbones). The observed antiviral activities of these oligonucleotides increased significantly when the PD backbone was replaced with a phosphorothioate (PT) backbone. Experiments designed to investigate a potential antiviral mechanism of action demonstrated that oligonucleotides tested were capable of blocking virus adsorption. In addition, GTOs with PD backbones were competitive inhibitors of FMLV reverse transcriptase (RT). When the same experiments were performed using oligonucleotides with PT backbones, all compounds tested demonstrated significant competitive inhibition of FMLV RT. The measured inhibitory activity of all compounds tested in culture assays was enhanced by at least a factor of 10 when the PD linkages were replaced with PT. The enhanced antiviral activity exhibited by the sulfur group on the oligonucleotide backbone, and the lack of any designed, sequence-specific interactions, suggest that a large percentage of the reported antiviral activity of oligonucleotides containing a phosphorothioate backbone is due to factors other than rationally designed, sequence-specific interactions. The ability of GTOs to inhibit FMLV in culture, potentially via a number of different mechanisms, makes this a class of compounds which warrants investigation as therapeutic agents to be used against retroviral infections.

Effect of imexon treatment on Friend virus complex infection using genetically defined mice as a model for HIV-1 infection

Imexon (4-imino-1,4-diazobicyclo-3.1.0-hexan-2-one) was moderately effective in the treatment of a retroviral infection in a genetically defined murine model. The animal model consisted of a Friend virus complex (FV) infection in a hybrid mouse strain, (B10.A x A/WySn)F1, which has similarities with acquired immune deficiency syndrome (AIDS). Intraperitoneal imexon initiated 1 or 3 days after FV inoculation and continued through 13 days after inoculation significantly reduced splenomegaly, splenic cell-free virus titers and viral RNA. Viral infectious centers/10(6) splenocytes and FV titers in the plasma were reduced, though not to a statistically significant level. The effect of imexon on survival was not statistically significant which suggested that the antiviral effects were only transiently effective. Phytohemagglutinin-induced blastogenesis and percent of total T cells, T helper cells and T suppressor/cytotoxic cells in the spleens were increased, and the percentage of B cells decreased by imexon treatment of both FV-infected and uninfected mice. The splenic natural killer cell activity and interleukin-1 production were not markedly affected. Virus specific neutralizing antibody developed in both imexon- and placebo-treated FV-infected mice, although titers were lower in the imexon-treated animals.

Metabolism of ganciclovir and cidofovir in cells infected with drug-resistant and wild-type strains of murine cytomegalovirus

Murine cytomegalovirus (MCMV) has been used extensively as an animal model for human cytomegalovirus (HCMV). Understanding drug resistance and its treatment in MCMV may lead to more effective treatments of HCMV disease. Most ganciclovir-resistant HCMV clinical isolates exhibit a decreased capacity to induce ganciclovir phosphorylation (to its biologically active form) in infected cells. Using an MCMV strain resistant to both ganciclovir and cidofovir, the intracellular metabolism of these drugs was studied to determine if MCMV resistance correlates with decreases in drug phosphorylation. The wild-type (WT) MCMV used for comparison was inhibited in plaque reduction assays, by ganciclovir and cidofovir by 50% at 5.1 and 0.24 microM, respectively; the resistant strain was inhibited at 72 and 2.7 microM, respectively. In uninfected, WT, or resistant virus-infected cells, the extent of metabolism of 10 microM ganciclovir or 1 microM cidofovir to intracellular triphosphorylated species was similar. Phosphorylation and catabolism (following drug removal) rates over time were also similar. Intracellular levels of ganciclovir triphosphate and cidofovir diphosphate increased less than two-fold with increasing multiplicity of virus infection. Because few differences in drug phosphorylation between WT and resistant virus-infected cells were found, virus resistance to ganciclovir and cidofovir apparently is not linked to altered drug phosphorylation. Since the viral DNA polymerase is the antiviral target for these compounds, the resistant MCMV is most likely a DNA polymerase mutant.

Immunomodulator Effects on the Friend Virus Infection in Genetically Defined Mice

The disease induced by the Friend virus complex (FV) in F1 hybrid mice containing the Rfv-3r/s genotype in the presence of H-2a/a was used to evaluate a variety of immunomodulating substances. In these genetically defined mice, the FV disease results in splenomegaly, early production of high titers of cell-associated and plasma virus, high levels of splenic viral RNA, increased hematocrit, and eventual death. As the disease progresses, reduced levels of infectious virus correlate with development of specific antibody; reduction in T cell populations, increase in B cells, and decrease in T-cell function also occur. The following immunomodulators were evaluated, listed in the order of their ability to inhibit the FV disease: imexon > MVE-2 > human recombinant IFN-alpha A/D > AS101 > ampligen > AM-3 = oxamisole > ImuVert > bropirimine. In fact, bropirimine, used with certain treatment regimens, appeared to enhance the FV disease. These data suggest that certain immunomodulators may have potential value in the treatment of HIV disease, but also indicate that caution should be exercised in their clinical use.

Elucidation of mode of retroviral-inhibitory effects of imexon through use of immune competent and severe combined immune deficiency (SCID) mice.

Mice infected with various tumor retroviruses have been used as models for evaluating therapeutic substances for the treatment of some cancers, and more recently, for human immunodeficiency virus (HIV) infection, the causative agent of acquired immune deficiency syndrome (AIDS). Consequently, there is a need to determine the ability of biological response modifiers (BRMs) to specifically reduce virus-infected cells, as compared to their non-specific anti-proliferative effects. To address this need, a BRM, imexon, was evaluated in this study using three strains of mice having different Friend virus (FV)-specific immunological capabilities. The first strain, (B10.A x A/WySn)F1, was genetically capable of producing FV-specific neutralization and cytotoxic antibodies, the second, Balb/c, was not, and the third, SCID mice, lacked functional T and B cell immunity. Imexon treatment reduced virally-induced splenomegaly in all 3 strains; however, the concentration of splenic viral infectious centers (IC) were not affected. Since imexon was efficacious in reducing splenomegaly in SCID mice, the mode of action was concluded to not require functional T or B cell immunity. The observation that imexon did not affect splenic IC titers also suggested that imexon did not specifically eliminate virally infected cells, but may have functioned by other mechanisms. This study also demonstrated the use of various mouse strains as a strategy for delineating the modes of action of BRMs against murine retroviral infections.

Murine retroviral disease-enhancing effects of a pyrimidinone immunomodulator

(B10.A x A/WySn)F1 mice, infected with the Friend virus (FV) complex, were used as a predictive therapeutic model for AIDS. These infected mice exhibit many of the viral and immunologic manifestations of AIDS. Bropirimine (2-amino-5-bromo-6-phenyl-4[3H]pyrimidinone, ABPP) is an immunomodulating compound which has been shown to inhibit other viral infections. Oral (per os treatment) dosages of ABPP ranging from 50 to 400 mg/kg/day for 3 days resulted in increased numbers of infectious centers in the infected mice and increased splenomegaly and percentage of Ig+ (B cells) in spleens of infected and uninfected mice. Decreased percentages of total Thy-1.2+ (total T) cells and L3T4+ (T-helper) cells were seen in both uninfected and infected mice and a slightly decreased percentage of Ly-2+ (T-suppressor/cytotoxic) cells was observed in spleens of the infected mice. No effect on Ly2+ cells in spleens of uninfected mice was found. Intraperitoneal injection, single or multiple, of 20-200 mg/kg ABPP prior to FV injection resulted in increased spleen weights but had no effect on numbers of infectious centers in the spleens or on FV antibody titers in the plasma. Intraperitoneal treatment of uninfected mice with ABPP resulted in slight or no changes in percentages of Thy-1.2+, L3T4+ and Ly-2+ cells. Mice receiving multiple exposures of ABPP had an increase in percentage of splenic B cells and a depressed response to the T cell mitogen PHA. Treatment with ABPP induced the production of interferon (IFN); however, a state of hyporesponsive IFN production was seen following multiple administrations of ABPP. These data suggest that the immunomodulator ABPP may have an enhancing effect on this retroviral disease.

Ganciclovir Treatment of Murine Cytomegalovirus Infection in Mice Immunosuppressed by Prior Infection with Friend Leukaemia Virus

Since many of the severe cytomegalovirus infections in humans occur in individuals immunosuppressed by the human immunodeficiency virus, we developed an analogous murine model for studying this disease. BALB/c mice infected with the Friend retrovirus complex (FV) were immunosuppressed (i.e., exhibited reduced spleen-cell mitogenic responses and natural killer cell activity) by 21 days after FV inoculation. Challenge with murine cytomegalovirus (MCMV) at that time led to mortality at doses generally non-lethal to normal mice. Superinfection of FV-infected mice with MCMV reduced spleen cell FV infectious centres and splenomegaly, and extended the lives of mice surviving the MCMV infection. Once-daily ganciclovir treatments of 12.5,25, and 50 mg kg−1 given to dually-infected mice for 5 days starting 24 h after MCMV inoculation resulted in 90–100% survival at 14 days (relative to MCMV inoculation) compared to 15% survival in the placebo group. By 70 days, survival in the drug-treated and placebo groups were 0–5%, these deaths being attributed to FV disease. Ganciclovir treatments reduced MCMV titres in spleen, liver, and kidney during treatment (day 4 of the infection), but lung and salivary gland titres rose between days 7 and 13 in surviving animals. Improved concanavalin A-induced mitogenic responses were noted on day 4 in mice treated with 25 and 50 mg kg−1. These results indicate that the FV/MCMV dual infection in mice can be used as a model for evaluating antiviral agents. Because of the complex nature of the interaction between FV and MCMV, the model may be more appropriate for advanced studies of well-defined viral inhibitors than for routine screening of potential new compounds.